A parsley 4CL-1 promoter fragment specifies complex expression patterns in transgenic tobacco.

The 4CL-1 gene is one of two highly homologous parsley genes encoding 4-coumarate:coenzyme A ligase, a key enzyme of general phenylpropanoid metabolism. Expression of these genes is essential for the biosynthesis of both defense-related and developmentally required phenylpropanoid derivatives. We examined the developmental regulation of the 4CL-1 promoter by analyzing the expression of 4CL-1-beta-glucuronidase fusions in transgenic tobacco plants. A 597-base pair 4CL-1 promoter fragment specified histochemically detectable expression in a complex array of vegetative and floral tissues and cell types. The activity of a series of 5' deleted promoter fragments was analyzed in parsley protoplasts and transgenic tobacco plants. Deletions past -210 base pairs led to a drastic decline in beta-glucuronidase activity in protoplasts and loss of tissue-specific expression in transgenic tobacco. These results were put into the context of potential protein-DNA interactions by in vivo footprint analysis of the 4CL-1 promoter in parsley cells. Loss of promoter activity in parsley protoplasts and transgenic tobacco was correlated with the deletion or disruption of the distal portion of a large (100-base pair) footprinted region within the first 200 base pairs of the 4CL-1 promoter.     

Role of Jasmonates in the Elicitor- and Wound-Inducible Expression of Defense Genes in Parsley and Transgenic Tobacco

Jasmonates have been proposed to be signaling intermediates in the wound and/or elicitor-activated expression of plant defense genes. We used parsley (Petroselinum crispum) cell cultures and transgenic tobacco (Nicotiana tabacum) plants expressing 4CL1-GUS gene fusions to investigate the potential role played by jasmonates in mediating the wound and/or elicitor activation of phenylpropanoid and other defense-related genes. Jasmonates and [alpha]-linolenic acid strongly induced the expression of 4CL in a dose-dependent manner in parsley cells; methyl jasmonate also activated the coordinate expression of other phenylpropanoid genes and the accumulation of furanocoumarin phytoalexins. However, the response of the cells to optimal methyl jasmonate concentrations was distinct quantitatively and qualitatively from the response of elicitor-treated cells. In transgenic tobacco wound-inducible tobacco 4CL genes and a 4CL1 promoter-GUS transgene were responsive to jasmonates and [alpha]-linolenic acid in a dose-dependent manner. Pre-treatment of parsley cells or tobacco leaves with a lipoxygenase inhibitor reduced their responsiveness to the elicitor and to wounding. These results show that the elicitor response in parsley cells can be partially mimicked by jasmonate treatment, which supports a role for jasmonates in mediating wound-induced expression of 4CL and other phenylpropanoid genes.     

Functional dissection of the promoter of the pollen-specific gene NTP303 reveals a novel pollen-specific, and conserved cis-regulatory element

Regulatory elements within the promoter of the pollen-specific NTP303 gene from tobacco were analysed by transient and stable expression analyses. Analysis of precisely targeted mutations showed that the NTP303 promoter is not regulated by any of the previously described pollen-specific cis -regulatory elements. However, two adjacent regions from −103 to −86 bp and from −86 to −59 bp were shown to contain sequences which positively regulated the NTP303 promoter. Both of these regions were capable of driving pollen-specific expression from a heterologous promoter, independent of orientation and in an additive manner. The boundaries of the minimal, functional NTP303 promoter were determined to lie within the region −86 to −51 bp. The sequence AAATGA localized from −94 to −89 bp was identified as a novel cis -acting element, of which the TGA triplet was shown to comprise an active part. This element was shown to be completely conserved in the similarly regulated promoter of the Bp10 gene from Brassica napus encoding a homologue of the NTP303 gene.     

Isolation of 4-coumarate Co-A ligase gene promoter from loblolly pine (Pinus taeda) and characterization of tissue-specific activity in transgenic tobacco

We characterized promoter activity of a phenylpropanoid biosynthetic gene encoding 4-coumarate Co-A ligase (4CL), Pta4Clα, from Pinus taeda. Histochemical- and quantitative assays of GUS expression in the vascular tissue were performed using transgenic tobacco plants expressing promoter-GUS reporters. Deletion analysis of the Pta4Clα promoter showed that the region ?524 to ?252, which has two AC elements, controls the high expression levels in ray-parenchyma cells of older tobacco stems. High activity level of the promoter domain of Pta4CLα was also detected in the xylem cells under bending stress. DNA-protein complexes were detected in the reactions of the Pta4CLα promoter fragments with the nuclear proteins of xylem of P. taeda. The AC elements in the Pta4CLα promoter appeared to have individual roles during xylem development that are activated in a coordinated manner in response to stress in transgenic tobacco.     

Tissue-specific and wound-inducible pattern of expression of the mannopine synthase promoter is determined by the interaction between positive and negative cis-regulatory elements

In transgenic tobacco plants the regulatory region of the Agrobacterium genes involved in mannopine synthesis ( pmas ) directs expression in vascular tissues and is induced upon wounding. To identify cis -acting sequences required for the cell-type-specific and wound-inducible expression of this regulatory region, the expression pattern of chimeric genes in which 5' upstream deletions of the pmas1' promoter direct the expression of the β-glucuronidase coding sequence, was analyzed in transgenic tobacco plants. It was found that the pmas1' promoter is specifically expressed in phloem cells and that this tissue-specific pattern of expression is the result of the interaction of at least two negative regulatory elements with a positive element that directs expression in many cell types. It was also found that wound induction is mediated by two different mechanisms, one of them involving a dramatic change in tissue-specific expression.     

Cooperation of two distinct cis-acting elements is necessary for the S phase-specific activation of the wheat histone H3 promoter

We have previously shown that the proximal promoter region (−185 to +57) of the wheat histone H3 gene ( TH012 ) is sufficient for regulating S phase-specific expression of a reporter GUS gene. To define the cis -acting element(s) responsible for S phase-specific expression, GUS fusion genes under the control of wild-type or variously mutated H3 promoters were stably introduced into cultured rice Oc cells and their temporal expression was analyzed during the cell cycle by quantitative S1 analysis. The S phase-specific expression of the full-sized promoter (−1716 to +52) was significantly impaired by short internal deletions disrupting the type I element from −175 to −158 (CCACGTCACCaATCCGCG), composed of the Hex (CCACG-TCA) and reverse-oriented Oct (GATCCGCG) motifs. Moreover, the H3 proximal promoters (−184 to +52) harboring base-substitution mutations in either or both of the Hex and Oct motifs could no longer activate gene expression during the S phase. These results indicate that the type I element is the first cis-acting element identified responsible for the S phase-specific expression of plant histone genes. Results also suggested the presence of a redundant cis -acting element(s) responsible for S phase-specific expression in the H3 far-upstream region (−1716 to −185).     

Structural characteristics of two wheat histone H2A genes encoding distinct types of variants and functional differences in their promoter activity

To investigate the regulation of plant histone H2A gene expression, we isolated two H2A genes (TH254 and TH274) from wheat, which encode two variants of H2A. Both genes had an intron in the coding region. In the promoters, some characteristic sequences, such as Oct and Nona motifs, which are conserved among plant histone genes, were located in a short region (about 120 bp) upstream from the putative TATA box. Transient expression analyses of promoter activity with H2A–GUS fusion genes using tobacco protoplasts revealed novel types of positive cis/-acting sequences in the TH254 promoter: a direct repeat of a 13 bp sequence (AGTTACATTATTG) and a stretch composed of an AT-rich sequence (ATATAGAAAATTAAAA) and a G-box (CACGTG). Quantitative S1 assay of the mRNA amounts from the TH254/GUS and TH274/GUS chimeric genes in stably transformed and cell cycle-synchronized tobacco cell lines showed that the promoters of both genes contained at least one cis/-acting element responsible for S phase-specific expression. Histochemical analysis of transgenic tobacco plants carrying the chimeric genes showed that the promoters of the two H2A genes were active in developing seedlings and flower organs but were regulated in a different manner.     

Isolation and Characterization of Two cDNAs Encoding 4-Coumarate:CoA Ligase in Lithospermum Cell Cultures

Two near full-length cDNAs (LE4CL-1, LE4CL-2), which encode4-coumarate:CoA ligase (4CL), were cloned from a library ofLithospermum erythrorhizon cell suspension cultures by the useof heterologous probe of potato 4CL. These cDNAs are 2.1 kband 2.2 kb in length, respectively. LE4CL-1 encodes 636 aminoacids, whose homologies to the 4CL protein sequences known topotato, parsley, pine and rice, were found to be 68%, 66%, 56%and 50% (identities on amino acid level), respectively, whereasthose of the predicted translation product of LE4CL-2 (594 aminoacids) to the above 4CL proteins were 49{small tilde}54%. Thesimilarity of the deduced amino acid sequences between the two4CLs from Lithospermum cell cultures was 49% in identity. Northernanalyses showed that the mRNA levels of both LE4CL-1 and LE4CL-2were much higher under illumination than in the dark, as reportedfor the 4CL genes of such plants as parsley. In comparison ofmRNA levels of LE4CL-1 and LE4CL-2, the former was demonstratedto be generally higher than the latter by means of an applicationof RT-PCR. The genomic southern blot experiments suggested thatthere are probably three copies of LE4CL-1 in the Lithospermumgenome DNA, whereas only one copy was detected for LE4CL-2. (Received May 26, 1995; Accepted August 16, 1995)